HD1024 High Definition Technology

HD1024 high definition technology enables 10 bits of vertical resolution with 4 GHz bandwidth. The HDO9000 automatically and dynamically determines the best ADC configuration under each specific measurement condition to always provide the optimal resolution.

Dynamic ADC Reconfiguration

HD1024 technology enables dynamic reconfiguration of the ADC to achieve 10 bits of vertical resolution. By automatically determining the best ADC configuration under each specific measurement condition, the HDO9000 always provides the optimal resolution.

Optimized Filtering

HD1024 high definition technology makes use of optimized filtering to provide additional resolution beyond 10-bits; extending up to 13.8 bits. When operating in low sample rate conditions, an anti-aliasing filter is automatically applied to reduce excess out-of-band noise. Additionally, resolution can be improved by applying a manual bandwidth limit on an individual channel.

Superior User Experience

The HDO9000 and MAUI with OneTouch allows users to perform all common operations with a single touch of the display, optimizing for convenience and efficiency. Meanwhile, the 15.4” high resolution capacitive touch screen’s bright display and quick responsiveness further enhances the inherent efficiency and intuitiveness of MAUI with OneTouch.

MAUI with OneTouch

The HDO9000 and MAUI with OneTouch sets the standard for oscilloscope user experience by providing the most unique touch features on any oscilloscope. Common gestures are used to instinctively interact with the oscilloscope and dramatically reduce setup time. Convenience and efficiency are optimized - all common operations can be performed with one touch and do not require opening and closing of pop-up dialogs or menus.

Exceptional Serial Data Tools

A wide a variety of application packages are available to meet all serial data test challenges, ranging from automated compliance packages to flexible debug toolkits. A suite of protocol specific measurement and eye diagram packages are available to complement the industry’s most intuitive trigger and decode packages.

Integrated Mixed Signal Capabilities

The HDO9000 High Definition Oscilloscopes offer powerful mixed signal solutions that combine high definition analog channels with the flexibility of digital inputs. The HDO9000-MS models are equipped with an integrated 16 digital channels and a 1.25 GS/s sampling rate which creates an all-in-one debug machine.

High-speed Digital Analyzer

For applications demanding even higher-performance mixed-signal acquisition capabilities, the HDA125 High-speed Digital Analyzer can be easily added to the HDO9000. With 12.5 GS/s digital sampling rate on 18 input channels and the revolutionary QuickLink probing solution, validation of challenging interfaces such as DDR memory has never been simpler or more comprehensive.

Serial Trigger, Decode, Measure/Graph, and Eye Diagrams

Isolate events using the serial bus trigger and view color-coded protocol information on top of analog or digital waveforms. Timing and bus measurements allow quick and easy characterization of a serial data system. Serial (digital) data can be extracted and graphed to monitor system performance over time. Identify physical layer anomalies with eye diagram mask testing and mask failure locator.

LabNotebook

LabNotebook automatically saves all displayed waveforms, oscilloscope setup file, and a screen with a single button press, eliminating the need to navigate multiple menus to save all these files independently. Report files can be annotated and shared with colleagues to fully document all results.

Q-Scape Multi-tab Display Architecture

Unique Q-Scape multitab display architecture speeds your understanding of your design with 4x the display area. Acquired or calculated waveforms can be located on any of four different “tabbed” oscilloscope grid displays, with individually selectable grid styles available for each tab. Quickly move waveforms to different tabs through drag-and-drop.

Jitter and Timing Analysis Option

JITKIT makes it simple and easy to understand the basic system jitter performance of clock signals and clock-data activities, including period, half period, cycle-cycle, skew, amplitude, differential voltage crossing, slew rate, and a wide variety of other common jitter measurements.

XDEV Advanced Customization Option

With the XDEV option, third party programs can be completely integrated into the oscilloscope’s processing stream. Create customized math functions and parameters using C/C++, MATLAB, Excel, JScript or Visual Basic without ever leaving the oscilloscope application - and view the results directly on the oscilloscope, in real-time.

Spectrum analyzer style user interface with controls for start/stop frequency or center frequency and span. Utilize up to 20 markers to automatically identify harmonics and quickly analyze frequency content. Monitor how the spectrum changes over time by viewing the spectrogram in 2D or 3D.

Understanding an electronic design's susceptibility to Electronmagnetic (EM) discharge is an important element of validation. Whether fast one time event transients or repetitive bursts EM can introduce unexpected events in the circuit performance. Teledyne LeCroy Oscilloscopes offer high sample rates and measurements tailored specifically to this task. Whether one pulse or billions of measurements engineers gain insight into their device and system suseptibility.

Serial Data Compliance

The USB package provides a complete acquisition and analysis system for USB 2.0 devices, hosts, and hubs, as specified in the USB-IF USB 2.0 Electrical Test Specification. The test software implements a full set of electrical tests for USB 2.0, including High-, Full-, and Low-speed tests and is supported by Teledyne LeCroy’s QualiPHY automated test and reporting software.

The Teledyne LeCroy QPHY-LPDDR2 Test Solution is the best way to characterize LPDDR2 memory interfaces. Capable of performing measurements on 466 MHz, 533 MHz, 667 MHz, 800 MHz, 900 Mhz, 1066 MHz and custom speed grades, QPHY-LPDDR2 has a full suite of Clock, Electrical and Timing tests as specified by the JEDEC Specifications.

Ethernet testing compliant with IEEE 802.3-2005 requires many test setups and connections and mask tests. Using Teledyne LeCroy QualiPHY-ENET these measurements are easy to setup and complete. Instructive connection diagrams and message boxes appear as pop ups on the oscilloscope screen. The connection diagram instructs the user how to change test fixture and jumper pins in order to do complete test. When the tests are complete, QualiPHY will generate a test report in PDF, HTML, or XML formats. Jitter and pulse mask tests are performed with automatic waveform alignment, and all test results feature pass/fail indicators corresponding to the standard being tested.

The Teledyne LeCroy QPHY-DDR3 Test Solution is the best way to characterize DDR3, DDR3L, and LPDDR3 memory interfaces. Capable of performing measurements on 800 MT/s, 1066 MT/s, 1333 MT/s, 1600 MT/s, 1866 MT/s, 2133 MT/s and custom speed grades, QPHY-DDR3 has a full suite of Clock, Electrical, and Timing tests as specified by the JEDEC Specification.

The Teledyne LeCroy QPHY-DDR2 Test Solution is the best way to characterize DDR2 memory interfaces. Capable of performing measurements on 400 MHz, 533 MHz, 667 MHz, 800 MHz, 1066 MHz and custom speed grades, QPHY-DDR2 has a full suite of Clock, Electrical and Timing tests as specified by the JEDEC Specification and Intel JEDEC Specifications Addendums.

GRL-USB-PD software provides a simple and efficient way to perform USB-PD electrical parametric and protocol measurements. GRL-USB-PD provides waveform visibility and protocol analysis making it ideal for design and debug of USB Type-C Power Delivery silicon and end products.

Automotive Ethernet enables faster data communication to meet the demands of today’s vehicles and the connected vehicles of the future. QPHY-BroadR-Reach automates testing and validation of 100 Mb/s Automotive Ethernet, which is described in both the BroadR-Reach and 100Base-T1 (IEEE 802.3bw) specifications.

Digital Filtering Software

Jitter Analysis Software

Validating system jitter performance and analyzing systems with high jitter levels comprises a significant portion of a system engineer's test and validation time. JITKIT makes it simple and easy to understand the basic system jitter performance of clock signals and clock-data activities, including period, half period, cyclecycle, skew, amplitude, differential voltage crossing, slew rate, and a wide variety of other common jitter measurements.

The comprehensive and intuitive deocde and easy to navigate table display enable a powerful toolset to quickly debug a USB 2.0 HSIC powered system. Combine it with ProtoSync to get a full view of all the USB 2.0 layers.

The MIPI UniPro Protocol Decoder analyzes acquired M-PHY analog waveforms and provides insight into multiple levels of UniPro protocol information. Data and Control frames are presented in an intuitive table format, where selecting a frame expands its content to a color-coded symbolic level, simultaneously creating a zoom. Decode annotation information is displayed on the physical layer waveform for a quick reference.

The MIPI System Power Management Interface (SPMI) decoder provides a fast and easy way to understand and correlate SPMI bus traffic to DC power rails and power management IC (PMIC) operations in mobile, handheld, and battery-powered embedded systems.

The SpaceWire decode adds a unique set of tools to your Teledyne LeCroy oscilloscope that simplifies the design, debug, and maintenance of SpaceWire systems. The high speed SpaceWire data stream is annotated directly on the physical layer waveforms. Various sections of the protocol are color-coded to make it easy to understand the protocol traffic. The decoder provides an interactive table, search, and zoom to make debugging fast and effective.

Manchester coding is a line code in which the encoding of each data bit has at least one transition and 1s and 0s have equal bit width and therefore has no DC component. Manchester signals are self-clocking, which means that a clock signal can be recovered from the encoded data. Manchester Configurable protocol decoder enables grouping bits using various combinations of bit rate, polarity, idle condition, time out and more to decipherable messages. It allows decode of various protocols developed using Manchester encoding scheme.

The MIPI M-PHY and D-PHY Decode and Physical Layer Test is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

The MIPI M-PHY and D-PHY Decode and Physical Layer Test is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

The Embedded Bundle Trigger and Decode (TD) contains the capabilities included in the I2Cbus, SPIbus, and UART-RS232bus TD products. For more information on this product, please see the product pages for I2Cbus TD, SPIbus TD, and UART-RS232bus TD.

The DigRF 3G and v4 decode are the ideal tools for powerful system level protocol debug as well as problem solving for signal quality issues. The DigRF decodes add a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI digital RF systems.

The DigRF 3G decode is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The DigRF 3G decode adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI digital RF systems.

The MIPI D-PHY decode is the ideal tool for powerful system level protocol debug as well as problem solving for signal quality issues. The D-PHY decode solution adds a unique set of tools to your oscilloscope, simplifying how you design and debug MIPI D-PHY, CSI-2 and DSI signals.

The CAN Trigger, Decode, Measure/Graph and Eye Diagram solution with Symbolic CAN support (TDME Symbolic) provides high performance triggers, transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value

The CAN FD Trigger, Decode, Measure/Graph and Eye Diagram solution with Symbolic support (TDME Symbolic) provides high performance triggers and transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug for both CAN and CAN FD. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value.

The CAN FD Trigger, Decode, Measure/Graph and Eye Diagram (TDME) solution provides high performance triggers and transparent color-coded decode overlays, protocol tables, and search capabilities, Measure/Graph (M) capability with automated measurement and graphing tools, and Eye Diagram (E) capability for physical layer signal assessment and debug for both CAN and CAN FD. Symbolic DBC files may be used to set up the trigger, display symbolic decodes, and select parameters for serial digital data extraction to an analog value.

The Media Data Input/Output (MDIO) decoder provides a fast and easy way to understand and correlate MDIO bus traffic to the management of PHYs or physical layer devices in media access controllers (MACs).